https://www.sages.org/basics-of-mechanical-ventilation-for-non-critical-care-mds/
SAGES BASICS OF MECHANICAL
VENTILATION FOR NON -CRITICAL CARE
MDS
March 21, 2020 by SAGES Webmaster
(drafted 3/19/2020 by the SAGES Acute Care Committee)
Background:
Although the data is still very early and treatment of COVID-19 respiratory failure
is still evolving, the current information suggests that the majority of critically ill
COVID-19 patients are suffering only from severe hypoxia and only require
management of hypoxemia using Positive End Expiration Pressure (PEEP), FiO2,
and possibly prone positioning. Other underlying chronic illnesses must be
treated accordingly, but again the effect of COVID-19 appears to be mostly
hypoxemia. Fluid resuscitation should be minimized to maintain euvolemia and
avoid hypervolemia. This primer can help provide some just in time learning for
non-critical care physicians who may be called to help manage ventilators.
Working with patients with confirmed or suspected COVID-19:
When the patients are coughing or on supplemental oxygen the respiratory
droplets can spread. Personal Protective Equipment (PPE) is essential for
provider protection, following current CDC guidelines (link). Gowns and gloves
for contact isolation and face protection will work when intubation is necessary.
Care must be taken when intubating to protect the providers and the patients
from harm. If the diagnosis is in question, or there is no testing available, a CT of
the chest may help with the diagnosis. With COVID-19, the hypoxemia is
profound, and the lung lesions are peripheral and ground glass in appearance.
Indications for mechanical ventilation:
Use of mechanical ventilation is indicated for when patients cannot maintain a
patent airway (after trauma, severe altered mental status, intoxicants), have
acute respiratory failure (resulting from sepsis or conditions like pancreatitis),
have compromised lung function (from conditions like pneumonia or cystic
fibrosis), and have difficulty breathing (weakness from frailty, pain from fracture
ribs).
Settings for mechanical ventilation:
In general, the clinician can determine the following parameters for mechanical
ventilation:
1. Respiratory rate: normal 10-16
2. Tidal Volume: amount of volume with each mechanical breath (mL per
breath)
3. Oxygen concentration: 20-100%
4. Positive End Expiration Pressure (PEEP): amount of pressure at the end of
the expiration that helps keep alveoli open for O2/CO2 exchange (typically 5-
20mmHg) Most patients should have at least a PEEP of 5 to start. Obese or
larger patients may need more PEEP.
5. Pressure Support ventilation: a mode of ventilation that adjusts the amount
of pressure used to keep the large airways open (typically 5-15mmHg),
which helps to decrease the work of breathing
6. Continuous mechanical ventilation (CMV): a full breath is given each time
the patient initiates a breath
Definitions
1. Assist Control: For every breath initiated by the patient, a total machine
volume/pressure will be delivered to the patient. If the patient does not
trigger a breath on their own, the ventilator will deliver a breath at a preset
rate
1. Volume controlled: a mechanical breath is delivered at a preset volume
2. Pressure controlled: a mechanical breath is delivered until a preset
pressure is reached
2. Pressure Support Ventilation: here the patient may not need full ventilator
assistance but is not yet strong enough to maintain adequate oxygenation
and ventilation for themselves or they are still unable to maintain their
airway.
Improving oxygenation:
Positive End Expiration Pressure (PEEP) can be raised to improve oxygen
exchange, typically 5-20 mm Hg. PEEP is used to increase functional capacity,
or the volume of gas retained in the lungs at the end of exhalation.
FiO2: increases the amount of oxygen delivered with each mechanical
breath. The goal of oxygen therapy is to maintain a saturation of 93-96% in
patients without underlying chronic pulmonary disease, and at 88-92% in patients
with chronic respiratory failure and/or severe COPD.
Inspiratory to Expiratory ratio: (I: E) normally this ratio is 1:3 meaning it takes
longer to expire than it does to inspire. By decreasing the ratio to 1:2 or 1:1, this
allows more time to inspire in oxygen, but it will cause the CO2 to rise. This
technique can also cause breath stacking and lead to a pneumothorax.
Permissive hypercapnia comes from allowing lower minute ventilation (which is
the respiratory rate x tidal volume) in patients with significant decreased lung
compliance, as in ARDS. The higher respiratory rate or tidal volume can injure
the alveoli, which would compromise oxygenation. As long as the pH can be
maintained above 7.2, the increased CO2 is allowed in order to preserve lung
function and maintain oxygenation. When using this technique in patients with
COPD, the patient may also experience breath stacking with auto PEEP,
meaning their end-expiratory pressure will be high or their peak pressures may
be high indicating a risk for more barotrauma. If this occurs, discuss the case
with the respiratory therapist who can help reduce the pressure in the lungs.
Improving ventilation:
Respiratory Rate: the rate is used to control the CO2 content in the serum. For
patients with hypercapnia (PaCO2 > 40), an increase in rate, >20 breaths per
minute, can improve this to help treat acidemia.
Tidal Volume: the volume of an inspired breath from ventilator can improve the
PaCO2 such that the larger the volume, the lower the PaCO2. Normally the
volume is set by either:
1. Volume control: the ventilator gives a set amount of volume. The
recommended tidal volume is 4-8 mL/kg, so a 70kg patient (ideal body
weight) would have volumes of 280 – 560 mL per breath. Respiratory rates
should be set at higher than normal, 18-25 breaths per minute. Peak
pressures should be maintained at less than 30cm H2O, and plateau
pressures at less than 15 cm H2O. This means that the patients should be
ventilated at faster rates and lower tidal volumes to prevent barotrauma.
2. Pressure control: the ventilator gives volume up until a certain
pressure. The pressure should be set to give a volume of 4-8cc/kg. In
general, pressures above 30cmH2O result in barotrauma that damages the
alveoli, which consequently worsens CO2 and O2 exchange. This will
typically occur in patients with decreased lung compliance as with ARDS.
Using the pressure-controlled technique allows the clinician to deliver an
appropriate volume without increasing the pressure.
Other considerations:
Providers should work closely with respiratory therapists to make sure each
patient is getting the support they need from the ventilator and that the ventilator
is not causing any morbidity.
Proper placement of an endotracheal tube is confirmed by end-tidal CO2 which
should be about 35-45 mmHg and a CXR with the tip of the endotracheal tube
approximately 2cm above the carina.
Patients on mechanical ventilation will likely require sedation and perhaps
paralysis to improve oxygenation and ventilation.
There are several parameters used for extubation including the Rapid-Shallow
Breathing Index and the PaO2/FiO2 ratio. In general, a PaO2/FiO2 ratio of 300 or
greater, and a RSBI of < 80 indicate that the patient is ready to wean from
mechanical ventilation. Patients should not be considered for extubation if they
require an Fi02 of more than 40% or a PEEP > 5 to maintain oxygenation.
Links:
REBELEM: Simplifying Mechanical Ventilation – Part I: Types of Breaths
AAST: Mechanical Ventilation in the Intensive Care Unit
Annals of Thoracic Medicine: Rapid shallow breathing index
VIDEO: Behind the Knife Podcast: Ventilators – Simplified By Dr. Patrick
Georgoff
NIH NHLBI ARDS Clinical Network: Mechanical Ventilation Protocol Summary
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